Optical lens module with plastic barrel, imaging apparatus including same module and electronic device including same apparatus

ABSTRACT

An optical lens module includes a lens assembly and a plastic barrel, The lens assembly includes a plurality of lens elements and is disposed in the plastic barrel. The plastic barrel includes an object-end portion, an image-end portion, an outer tube portion, an inner tube portion and at least one reflection reduction area. The image-end portion includes an image-end opening. The inner tube portion includes a plurality of parallel inner surfaces and a plurality of inclined inner surfaces, wherein the parallel inner surfaces are parallel to the central axis, and each of the inclined inner surfaces has an angle with the central axis. The reflection reduction area is disposed on one of the inclined inner surfaces closest to the image-end opening, wherein the reflection reduction area and the plastic barrel are integrally formed by an injection molding method.

RELATED APPLICATIONS

The present application is a continuation of the application Ser. No.14/851,773, filed Sep. 11, 2015, which is herein incorporated byreference.

BACKGROUND

Technical Field

The present disclosure relates to an optical lens module and an imagingapparatus. More particularly, the present disclosure relates to anoptical lens module and an imaging apparatus which is applicable toportable electronic devices.

Description of Related Art

Due to the popularity of personal electronic products and mobilecommunication products having camera functionalities, such as smartphones and tablet personal computers, the demand for compact imagingapparatuses has been increasing, and the requirements for highresolution and image quality of present compact imaging apparatusesincrease significantly.

With the trends of the high-pixels camera functionalities of personalelectronic products and mobile communication products, the dimension ofthe imaging apparatus has been increasing such as the diameter of thelens element closest to the image surface of the imaging apparatusreaching 6 mm. On the other hand, the back focal length of the imagingapparatus is still kept short. Hence, more and more non-imaging light isreflected from the surface of the IR-cut filter (infrared-cut filter) tothe surfaces of the lens elements, as well as the incident angles on thesurfaces of the lens elements are usually greater than the criticalangle of the total reflection thereof, so that the reflection from thesurfaces of the lens elements to the image surface of the imagingapparatus has been increased, and it results in the ghost image on theimage surface of the imaging apparatus.

FIG. 1 is a schematic view of a conventional imaging apparatus 9000.According to the conventional imaging apparatus 9000, the non-imaginglight Lia would be reflected from the object-side surface 9601 of theIR-cut filter 9600 to the inner wall 9521 of the plastic barrel 9520,and would be reflected from the inner wall 9521 of the plastic barrel9520 to the object-side surface 9511 of the lens element 9510 as thenon-imaging light Loa, wherein the non-imaging light Loa is attenuatedlittle from the non-imaging light Lia, so that the strength of thenon-imaging light Loa is still approach to the strength of thenon-imaging light Lia.

As well as the incident angle θ on the object-side surface 9511 of thelens element 9510 is greater than the critical angle θ_(c) of the totalreflection thereof, so that the reflection from the object-side surface9511 of the lens element 9510 to the image surface 9700 of theconventional imaging apparatus 9000 results in the ghost image on theimage surface 9700 of the conventional imaging apparatus 9000.

If the index of refraction of the lens element 9510 in d-line referencewavelength (587.6 nm) is 1.535, then the critical angle θ_(c) of thetotal reflection of the lens element 9510 is 40.65 degrees as thefollowing:

$\theta_{c} = {{\sin^{- 1}\left( \frac{N_{air}}{N_{lens}} \right)} = {{\sin^{- 1}\left( \frac{1}{1.535} \right)} = {40.65\mspace{14mu} {{degrees}.}}}}$

Herein, N_(air) is the index of refraction of air, which is 1 byassumption, N_(lens) is the index of refraction of the lens element9510. Furthermore, with the greater diameter of the lens element 9510,more non-imaging light with incident angle above 40.65 degrees has beenreflected.

Another instance, if the index of refraction of the lens element ind-line reference wavelength (587.6 nm) is 1.544, then the critical angleθ_(c) of the total reflection of the lens element is 40.37 degrees asthe following:

$\theta_{c} = {{\sin^{- 1}\left( \frac{N_{air}}{N_{lens}} \right)} = {{\sin^{- 1}\left( \frac{1}{1.544} \right)} = {40.37\mspace{14mu} {{degrees}.}}}}$

However, the aforementioned problems are difficult to solve by theconventional coating of the lens elements. Therefore, the conventionalcoating cannot satisfy the requirements of reducing the reflectionresulting in the ghost image on the image surface of the imagingapparatus.

In view of the above, how to reduce the total reflection of non-imaginglight resulting in the ghost image on the image surface for enhancingthe image quality of compact imaging apparatuses has become one of theimportant subjects.

SUMMARY

According to one aspect of the present disclosure, an optical lensmodule includes a lens assembly and a plastic barrel. The lens assemblyincludes a plurality of lens elements and is disposed in the plasticbarrel. The plastic barrel includes an object-end portion, an image-endportion, an outer tube portion, an inner tube portion and at least onereflection reduction area. The object-end portion includes an object-endsurface and an object-end hole. The image-end portion includes animage-end opening. The outer tube portion connects the object-endportion and the image-end portion. The inner tube portion connects theobject-end portion and the image-end portion, wherein the inner tubeportion is closer to a central axis of the plastic barrel than the outertube portion. The inner tube portion includes a plurality of parallelinner surfaces and a plurality of inclined inner surfaces, wherein theparallel inner surfaces are parallel to the central axis, and each ofthe inclined inner surfaces has an angle with the central axis. Thereflection reduction area is disposed on one of the inclined innersurfaces closest to the image-end opening, wherein the reflectionreduction area and the plastic barrel are integrally formed by aninjection molding method.

According to another aspect of the present disclosure, an imagingapparatus includes the optical lens module according to the foregoingaspect, an IR-cut filter and an image sensor. The IR-cut filter isdisposed out of the plastic barrel. The image sensor is disposed on animage surface of the optical lens module, and the IR-cut filter isdisposed between the plastic barrel and the image sensor.

According to another aspect of the present disclosure, an electronicdevice includes the imaging apparatus according to the foregoing aspect.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a conventional imaging apparatus;

FIG. 2A is a schematic view of an optical lens module according to the1st embodiment of the present disclosure;

FIG. 2B shows a schematic view of the parameters α and φ of the opticallens module according to the 1st embodiment;

FIG. 2C shows a schematic view of the molding part of the plastic barrelaccording to the 1st embodiment;

FIG. 3A is a schematic view of an optical lens module according to the2nd embodiment of the present disclosure;

FIG. 3B shows a schematic view of the parameters α and φ of the opticallens module according to the 2nd embodiment;

FIG. 4A is a schematic view of an optical lens module according to the3rd is embodiment of the present disclosure;

FIG. 4B shows a schematic view of the parameters α and φ of the opticallens module according to the 3rd embodiment;

FIG. 5A is a schematic view of an optical lens module according to the4th embodiment of the present disclosure;

FIG. 5B shows a schematic view of the parameters α and φ of the opticallens module according to the 4th embodiment;

FIG. 6A is a schematic view of an optical lens module according to the5th embodiment of the present disclosure;

FIG. 6B shows a schematic view of the parameter α and φ of the opticallens module according to the 5th embodiment;

FIG. 7A is a schematic view of an optical lens module according to the6th embodiment of the present disclosure;

FIG. 7B shows a schematic view of the parameters α and φ of the opticallens module according to the 6th embodiment;

FIG. 8 shows an imaging apparatus according to the 7th embodiment of thepresent disclosure;

FIG. 9 shows an imaging apparatus according to the 8th embodiment of thepresent disclosure;

FIG. 10 shows an electronic device according to the 9th embodiment ofthe present disclosure;

FIG. 11 shows an electronic device according to the 10th embodiment ofthe present disclosure; and

FIG. 12 shows an electronic device according to the 11th embodiment ofthe present disclosure.

DETAILED DESCRIPTION 1st Embodiment

FIG. 2A is a schematic view of an optical lens module 100 according tothe 1st embodiment of the present disclosure. In the 1st embodiment, anoptical . lens module 100 includes a lens assembly 110 and a plasticbarrel 120.

The lens assembly 110 includes a plurality of lens elements (111-116)and is disposed in the plastic barrel 120. The plastic barrel 120includes an object-end portion 130, an image-end portion 140, an outertube portion 150, an inner tube portion 160 and at least one reflectionreduction area 170. The object-end portion 130 includes an object-endsurface 131 and an object-end hole 132. The image-end portion 140includes an image-end opening 141. The outer tube portion 150 connectsthe object-end portion 130 and the image-end portion 140. The inner tubeportion 160 connects the object-end portion 130 and the image-endportion 140, wherein the inner tube portion 160 is closer to a centralaxis of the plastic barrel 120 than the outer tube portion 150. Theinner tube portion 160 includes a plurality of parallel inner surfaces161 and a plurality of inclined inner surfaces 162, wherein the parallelinner surfaces 161 are parallel to the central axis, and each of theinclined inner surfaces 162 has an angle with the central axis, whichcan be greater than 0 degrees and less than 90 degrees. In other words,the each of the inclined inner surfaces 162 is neither parallel nororthogonal to the central axis. The reflection reduction area 170 isdisposed on one of the inclined inner surfaces 162 closest to the isimage-end opening 141, wherein the reflection reduction area 170 and theplastic barrel 120 are integrally formed by an injection molding method.Therefore, it is favorable for reducing the ghost image resulted fromthe non-imaging light totally reflected from the lens element to theimage surface and improving the image quality by the reflectionreduction area 170 disposed close to the image-end opening 141, so thatthe optical lens module 100 can be applied to the cameras withhigh-pixels.

In FIG. 2A, the non-imaging light Li would be reflected from the surfaceof the IR-cut filter (not shown) to the reflection reduction area 170 ofthe plastic barrel 120, and would be reflected from the reflectionreduction area 170 of the plastic barrel 120 to the object-side surface117 of the lens element 116 as the non-imaging light Lo, wherein thenon-imaging light Lo is attenuated much from the non-imaging light Li,so that the strength of the non-imaging light Lo is much less than thestrength of the non-imaging light Li. Therefore, it is favorable forreducing the ghost image resulted from the non-imaging light totallyreflected from the lens element to the image surface.

In details, the plastic barrel 120 can be made of polycarbonatematerial. Therefore, it is favorable for maintaining the low reflectionof the reflection reduction area 170. In the 1st embodiment, the plasticbarrel 120 is made of black polycarbonate material.

FIG. 2B shows a schematic view of the parameters α and φ of the opticallens module 100 according to the 1st embodiment. When an angle betweenthe one of the inclined inner surfaces 162 closest to the image-endopening 141, which the reflection reduction area 170 is disposedthereon, and the central axis is α, the following condition can besatisfied: 1.0 degrees<α<25.0 degrees. Therefore, it is favorable formaintaining the low reflection and the manufacturing quality of thereflection reduction area 170 and the plastic barrel 120. Preferably,the following condition is satisfied: 2.0 degrees<α<20.0 degrees.

FIG. 2C shows a schematic view of the molding part of the plastic barrel120 according to the 1st embodiment. A surface finishing portion 190corresponds to the reflection reduction area 170, and a surface of thesurface finishing portion 190 can be processed by sand-blasting,electrical discharge machining (EDM), or laser related etching methods.As a consequence, the surface property of the surface finishing portion190 would be transferred to the reflection reduction area 170 in aplastic injection molding process, so we can say the reflectionreduction area 170 is formed by sand-blasting, electrical dischargemachining, or laser related etching methods indirectly, or we can saythe reflection reduction area 170 is manufactured by sand-blasting,electrical discharge machining, or laser related etching methods. Itshould be noted that FIG. 2C is for expressing how sand-blastingindirectly is enforced, instead of a limited disclosure of molding ofthe plastic barrel 120.

Moreover, a number of the reflection reduction area 170 can be at leastthree, and the three reflection reduction areas 170 are disposed on theone of the inclined inner surfaces 162 closest to the image-end opening141, the object-end portion 130 and the image-end portion 140,respectively. According to the 1st embodiment of the present disclosure,the optical lens module 100 includes one reflection reduction area 170disposed on the one of the inclined inner surfaces 162 closest to theimage-end opening 141. Therefore, it is favorable for obtaining the lowreflection of the reflection reduction areas 170 and the superior yieldrate of the injection molding method. Furthermore, the is reflectionreduction areas 170 can be formed by sand-blasting indirectly.Therefore, it is favorable for obtaining the optimally low reflection ofthe plastic barrel 120.

According to the 1st embodiment of the present disclosure, when asurface roughness of the reflection reduction area 170 is Ra, thefollowing condition can be satisfied: 0.18 μm<Ra<3.5 μm. Therefore, itis favorable for maintaining the low reflection of the reflectionreduction area 170.

In details, the lens assembly 110 includes, in order from an object sideto an image side, a first lens element 111, a second lens element 112, athird lens element 113, a fourth lens element 114, a fifth lens element115 and a sixth lens element 116, wherein the sixth lens element 116 isthe one of the lens elements closest to the image-end opening 141.

According to the 1st embodiment of the present disclosure, when arefractive index of the one of the lens elements closest to theimage-end opening 141 (the sixth lens element 116) is n, the followingcondition can be satisfied: 1.45<n<1.62. Therefore, it is favorable forincreasing the critical angle of the sixth lens element 116 so as toreduce the total reflection thereon.

In FIG. 2B, when an outer diameter of the one of the lens elementsclosest to the image-end opening 141 (the sixth lens element 116) is α,the following condition can be satisfied: 5.85 mm<α<9.5 mm. Therefore,it is favorable for satisfying the optical requirements of high-pixels.

According to the 1st embodiment of the present disclosure, a number ofthe parallel inner surfaces 161 can be at least six. Therefore, it isfavorable for obtaining the convenience of assembling of the lensassembly 110 so as to reduce the disorder among the lens elements duringassembling.

According to the 1st embodiment of the present disclosure, at leastthree of the lens elements can be connected to the parallel innersurfaces 161. Therefore, it is favorable for obtaining the betterresolution of the optical lens module 100.

According to the 1st embodiment of the present disclosure, the opticallens module 100 can further include an annular retaining member 180,which is for disposing the lens assembly 110 in the plastic barrel 120.Therefore, it is favorable for maintaining the assembling stability ofthe optical lens module 100. Furthermore, the annular retaining member180 is located on the inner tube portion 160 and near the image-endopening 141.

According to the 1st embodiment of the present disclosure, at least oneof the parallel inner surfaces 161 can be connected to the annularretaining member 180. Therefore, it is favorable for maintaining theassembling stability of the optical lens module 100.

The data of the aforementioned parameters of the optical lens module 100according to the 1st embodiment of the present disclosure are listed inthe following Table 1A, wherein a value of the surface finishingcorresponding to Ra is VDI (Verein Deutscher lngenieure), and a draftingangle corresponding to Ra is DA-PC. The data are also shown as FIG. 2B.

In addition, the corresponding values of VDI, Ra, DA-PC, DA-PA andDA-ABS are listed in the following Table 1B and for general reference,wherein DA-PC, DA-PA and DA-ABS are the draft angles of the materials ofpolycarbonate, polyamide and acrilnitrile-butadiene-styrol respectively,and the relationship between VDI and Ra is as following:VDI=20×log(10×Ra). It is should be noted that the actual angles ofDA-PC, DA-PA and DA-ABS may differ from 0.5 degrees to 1 degrees amongindividual manufacturers.

TABLE 1A 1st Embodiment Φ (mm) 6.4 Ra (μm)  0.4~0.56 n 1.535 VDI 12~15 α(deg.) 4.8 DA-PC (deg.) 1 Reference wavelength for parameter n is 587.6nm (d-line).

TABLE 1B Reference of Surface Roughness VDI Ra (μm) DA-PC (deg.) DA-PA(deg.) DA-ABS (deg.) 10 0.32 1.0 0.0 0.5 12 0.40 1.0 0.0 0.5 15 0.56 1.00.5 0.5 18 0.80 1.0 0.5 0.5 21 1.12 1.0 0.5 0.5 24 1.60 1.5 0.5 1.0 272.24 2.0 1.0 1.5 30 3.15 2.0 1.5 2.0 33 4.50 3.0 2.0 2.5 36 6.30 4.0 2.53.0 39 9.00 5.0 3.0 4.0 42 12.50 6.0 4.0 5.0

2nd Embodiment

FIG. 3A is a schematic view of an optical lens module 200 according tothe 2nd embodiment of the present disclosure. In the 2nd embodiment, anoptical lens module 200 includes a lens assembly 210, a plastic barrel220 and an annular retaining member 280.

The lens assembly 210 includes a plurality of lens elements (211-216)and is disposed in the plastic barrel 220. The plastic barrel 220includes an object-end portion 230, an image-end portion 240, an outertube portion 250, an inner tube portion 260 and a reflection reductionarea 270. The object-end portion 230 includes an object-end surface 231and an object-end hole 232. The image-end portion 240 includes animage-end opening 241. The outer tube portion 250 connects theobject-end portion 230 and the image-end portion 240. The inner tubeportion 260 connects the object-end portion 230 and the is image-endportion 240, wherein the inner tube portion 260 is closer to a centralaxis of the plastic barrel 220 than the outer tube portion 250. Theinner tube portion 260 includes a plurality of parallel inner surfaces261 and a plurality of inclined inner surfaces 262, wherein the parallelinner surfaces 261 are parallel to the central axis, and each of theinclined inner surfaces 262 has an angle with the central axis. Thereflection reduction area 270 is disposed on one of the inclined innersurfaces 262 closest to the image-end opening 241, wherein thereflection reduction area 270 and the plastic barrel 220 are integrallyformed by an injection molding method. Furthermore, the plastic barrel220 is made of black polycarbonate material, and the reflectionreduction area 270 is formed by sand-blasting indirectly.

The lens assembly 210 includes, in order from an object side to an imageside, a first lens element 211, a second lens element 212, a third lenselement 213, a fourth lens element 214, a fifth lens element 215 and asixth lens element 216, wherein the sixth lens element 216 is the one ofthe lens elements closest to the image-end opening 241.

A number of the parallel inner surfaces 261 is at least six, and atleast three of the lens elements are connected to the parallel innersurfaces 261.

The annular retaining member 280, which is located on the inner tubeportion 260 and near the image-end opening 241, is for disposing thelens assembly 210 in the plastic barrel 220, and at least one of theparallel inner surfaces 261 is connected to the annular retaining member280.

FIG. 3B shows a schematic view of the parameters α and φ of the opticallens module 200 according to the 2nd embodiment. The data of theparameters α, n, φ, Ra, VDI and DA-PC of the optical lens module 200according to the 2nd embodiment of the present disclosure are listed inthe following Table 2. The definitions of these parameters shown inTable 2 are the same as those stated in the 1st embodiment withcorresponding values for the 2nd embodiment.

TABLE 2 2nd Embodiment Φ (mm) 7 Ra (μm) 1.12~1.6 n 1.535 VDI 23 α (deg.)5.4 DA-PC (deg.)   1~1.5 Reference wavelength for parameter n is 587.6nm (d-line).

3rd Embodiment

FIG. 4A is a schematic view of an optical lens module 300 according tothe 3rd embodiment of the present disclosure. In the 3rd embodiment, anoptical lens module 300 includes a lens assembly 310, a plastic barrel320 and an annular retaining member 380.

The lens assembly 310 includes a plurality of lens elements (311-316)and is disposed in the plastic barrel 320. The plastic barrel 320includes an object-end portion 330, an image-end portion 340, an outertube portion 350, an inner tube portion 360 and a reflection reductionarea 370. The object-end portion 330 includes an object-end surface 331and an object-end hole 332. The image-end portion 340 includes animage-end opening 341. The outer tube portion 350 connects theobject-end portion 330 and the image-end portion 340. The inner tubeportion 360 connects the object-end portion 330 and the image-endportion 340, wherein the inner tube portion 360 is closer to a centralaxis of the plastic barrel 320 than the outer tube portion 350. Theinner tube portion 360 includes a plurality of parallel inner surfaces361 and a plurality of inclined inner surfaces 362, wherein the parallelinner surfaces 361 are parallel to the central axis, and each of theinclined inner surfaces 362 has an angle with the central axis. Thereflection reduction area 370 is disposed on one of the inclined innersurfaces 362 closest to the image-end opening 341, wherein thereflection reduction area 370 and the plastic barrel 320 are integrallyformed by an injection molding method. Furthermore, the plastic barrel320 is made of black polycarbonate material, and the reflectionreduction area 370 is formed by sand-blasting indirectly.

The lens assembly 310 includes, in order from an object side to an imageside, a first lens element 311, a second lens element 312, a third lenselement 313, a fourth lens element 314, a fifth lens element 315 and asixth lens element 316, wherein the sixth lens element 316 is the one ofthe lens elements closest to the image-end opening 341.

A number of the parallel inner surfaces 361 is at least six, and atleast three of the lens elements are connected to the parallel innersurfaces 361.

The annular retaining member 380, which is located on the inner tubeportion 360 and near the image-end opening 341, is for disposing thelens assembly 310 in the plastic barrel 320, and at least one of theparallel inner surfaces 361 is connected to the annular retaining member380.

FIG. 4B shows a schematic view of the parameters α and φ of the opticallens module 300 according to the 3rd embodiment. The data of theparameters φ, n, α, Ra, VDI and DA-PC of the optical lens module 300according to the 3rd embodiment of the present disclosure are listed inthe following Table 3. The definitions of these parameters shown inTable 3 are the same as those stated in the 1st embodiment withcorresponding values for the 3rd embodiment.

TABLE 3 3rd Embodiment Φ (mm) 6 Ra (μm) 0.4~0.8 n 1.544 VDI 12~18 α(deg.) 3.0 DA-PC (deg.) 1 Reference wavelength for parameter n is 587.6nm (d-line).

4th Embodiment

FIG. 5A is a schematic view of an optical lens module 400 according tothe 4th embodiment of the present disclosure. In the 4th embodiment, anoptical lens module 400 includes a lens assembly 410, a plastic barrel420 and an annular retaining member 480.

The lens assembly 410 includes a plurality of lens elements (411-416)and is disposed in the plastic barrel 420. The plastic barrel 420includes an object-end portion 430, an image-end portion 440, an outertube portion 450, an inner tube portion 460 and a reduction area 470.The object-end portion 430 includes an object-end surface 431 and anobject-end hole 432. The to image-end portion 440 includes an image-endopening 441. The outer tube portion 450 connects the object-end portion430 and the image-end portion 440. The inner tube portion 460 connectsthe object-end portion 430 and the image-end portion 440, wherein theinner tube portion 460 is closer to a central axis of the plastic barrel420 than the outer tube portion 450. The inner tube portion 460 includesa plurality of parallel inner surfaces 461 and a plurality of inclinedinner surfaces 462, wherein the parallel inner surfaces 461 are parallelto the central axis, and each of the inclined inner surfaces 462 has anangle with the central axis. The reflection reduction area 470 isdisposed on one of the inclined inner surfaces 462 closest to theimage-end opening 441, wherein the reflection reduction area 470 and theplastic barrel 420 are integrally formed by an injection molding method.Furthermore, the plastic barrel 420 is made of black polycarbonatematerial, and the reflection reduction area 470 is formed by electricaldischarge machining indirectly.

The lens assembly 410 includes, in order from an object side to an imageside, a first lens element 411, a second lens element 412, a third lenselement 413, a fourth lens element 414, a fifth lens element 415 and asixth lens element 416, wherein the sixth lens element 416 is the one ofthe lens elements closest to the image-end opening 441.

A number of the parallel inner surfaces 461 is at least six, and atleast three of the lens elements are connected to the parallel innersurfaces 461.

The annular retaining member 480, which is located on the inner tubeportion 460 and near the image-end opening 441, is for disposing thelens assembly 410 in the plastic barrel 420, and at least one of theparallel inner surfaces 461 is connected to the annular retaining member480.

FIG. 5B shows a schematic view of the parameters α and φ of the opticallens module 400 according to the 4th embodiment. The data of theparameters φ, n, α, Ra, VDI and DA-PC of the optical lens module 400according to the 4th embodiment of the present disclosure are listed inthe following Table 4. The definitions of these parameters shown inTable 4 are the same as those stated in is the 1st embodiment withcorresponding values for the 4th embodiment.

TABLE 4 4th Embodiment Φ (mm) 6.3 Ra (μm) 0.4~0.56 n 1.544 VDI 12~15  α(deg.) 2.1 DA-PC (deg.) 1 Reference wavelength for parameter n is 587.6nm (d-line).

5th Embodiment

FIG. 6A is a schematic view of an optical lens module 500 according tothe 5th embodiment of the present disclosure. In the 5th embodiment, anoptical lens module 500 includes a lens assembly 510, a plastic barrel520 and an annular retaining member 580.

The lens assembly 510 includes a plurality of lens elements (511-516)and is disposed in the plastic barrel 520, The plastic barrel 520includes an object-end portion 530, an image-end portion 540, an outertube portion 550, an inner tube portion 560 and a reflection reductionarea 570. The object-end portion 530 includes an object-end surface 531and an object-end hole 532.

The image-end portion 540 includes an image-end opening 541. The outertube portion 550 connects the object-end portion 530 and the image-endportion 540. The inner tube portion 560 connects the object-end portion530 and the image-end portion 540, wherein the inner tube portion 560 iscloser to a central axis of the plastic barrel 520 than the outer tubeportion 550. The inner tube portion 560 includes a plurality of parallelinner surfaces 561 and a plurality of inclined inner surfaces 562,wherein the parallel inner surfaces 561 are parallel to the centralaxis, and each of the inclined inner surfaces 562 has an angle with thecentral axis. The reflection reduction area 570 is disposed on one ofthe is inclined inner surfaces 562 closest to the image-end opening 541,wherein the reflection reduction area 570 and the plastic barrel 520 areintegrally formed by an injection molding method. Furthermore, theplastic barrel 520 is made of black polycarbonate material, and thereflection reduction area 570 is formed by electrical dischargemachining Indirectly.

The lens assembly 510 includes, in order from an object side to an imageside, a first lens element 511, a second lens element 512, a third lenselement 513, a fourth lens element 514, a fifth lens element 515 and asixth lens element 516, wherein the sixth lens element 516 is the one ofthe lens elements closest to the image-end opening 541.

A number of the parallel inner surfaces 561 is at least six, and atleast three of the lens elements are connected to the parallel innersurfaces 561.

The annular retaining member 580, which is located on the inner tubeportion 560 and near the image-end opening 541, is for disposing thelens assembly 510 in the plastic barrel 520, and at least one of theparallel inner surfaces 561 is connected to the annular retaining member580.

FIG. 6B shows a schematic view of the parameters α and φ of the opticallens module 500 according to the 5th embodiment, The data of theparameters φ, n, α, Ra, VDI and DA-PC of the optical lens module 500according to the 5th embodiment of the present disclosure are listed inthe following Table 5. The definitions of these parameters shown inTable 5 are the same as those stated in the 1st embodiment withcorresponding values for the 5th embodiment.

TABLE 5 5th Embodiment Φ (mm) 6.7 Ra (μm) 2.24~3.15 n 1.544 VDI 29 α(deg.) 7.3 DA-PC (deg.) 1 Reference wavelength for parameter n is 587.6nm (d-line).

6th Embodiment

FIG. 7A is a schematic view of an optical lens module 600 according tothe 6th embodiment of the present disclosure. In the 6th embodiment, anoptical lens module 600 includes a lens assembly 610, a plastic barrel620 and an annular retaining member 680.

The lens assembly 610 includes a plurality of lens elements (611-616)and is disposed in the plastic barrel 620. The plastic barrel 620includes an object-end portion 630, an image-end portion 640, an outertube portion 650, an inner tube portion 660 and at least threereflection reduction areas 670. The object-end portion 630 includes anobject-end surface 631 and an object-end hole 632. The image-end portion640 includes an image-end opening 641. The outer tube portion 650connects the object-end portion 630 and the image-end portion 640, Theinner tube portion 660 connects the object-end portion 630 and theimage-end portion 640, wherein the inner tube portion 660 is closer to acentral axis of the plastic barrel 620 than the outer tube portion 650.The inner tube portion 660 includes a plurality of parallel innersurfaces 661 and a plurality of inclined inner surfaces 662, wherein theparallel inner surfaces 661 are parallel to the central axis, and eachof the inclined inner surfaces 662 has to an angle with the centralaxis. The reflection reduction areas 670 are disposed on the inclinedinner surfaces 662, especially the one of the inclined inner surfaces662 closest to the image-end opening 641, the object-end portion 630 andthe image-end portion 640, wherein the reflection reduction areas 670and the plastic barrel 620 are integrally formed by an injection moldingmethod. Furthermore, the plastic barrel 620 is made of blackpolycarbonate material, and the reflection reduction areas 670 areformed by laser related etching methods or the like indirectly.

The lens assembly 610 includes, in order from an object side to an imageside, a first lens element 611, a second lens element 612, a third lenselement 613, a fourth lens element 614, a fifth lens element 615 and asixth lens element 616, wherein the sixth lens element 616 is the one ofthe lens elements closest to the image-end opening 641.

A number of the parallel inner surfaces 661 is at least six, and atleast three of the lens elements are connected to the parallel innersurfaces 661.

The annular retaining member 680, which is located on the inner tubeportion 660 and near the image-end opening 641, is for disposing thelens assembly 610 in the plastic barrel 620, and at least one of theparallel inner surfaces 661 is connected to the annular retaining member680.

FIG. 7B shows a schematic view of the parameters α and φ of the opticallens module 600 according to the 6th embodiment. The data of theparameters φ, n, , Ra, VDI and DA-PC of the optical lens module 600according to the 6th embodiment of the present disclosure are listed inthe following Table 6. The definitions of these parameters shown inTable 6 are the same as those stated in to the 1st embodiment withcorresponding values for the 6th embodiment.

TABLE 6 6th Embodiment Φ (mm) 6.4 Ra (μm) 2.2~2.3 n 1.544 VDI 27 α(deg.) 16.3 DA-PC (deg.) 2 Reference wavelength for parameter n is 587.6nm (d-line).

7th Embodiment

FIG. 8 shows an imaging apparatus 1000 according to the 7th embodimentof the present disclosure. In the 7th embodiment, an imaging apparatus1000 includes the optical lens module 100 according to the 1stembodiment of the present disclosure, an IR-cut filter 1100 and an imagesensor 1300.

In FIG. 2A, the optical lens module 100 includes the lens assembly 110,the plastic barrel 120 and the annular retaining member 180. The lensassembly 110 includes the lens elements (111-116) and is disposed in theplastic barrel 120. The plastic barrel 120 includes the object-endportion 130, the image-end portion 140, the outer tube portion 150, theinner tube portion 160 and the reflection reduction area 170. Theobject-end portion 130 includes the object-end surface 131 and theobject-end hole 132. The image-end portion 140 includes the image-endopening 141. The outer tube portion 150 connects the object-end portion130 and the image-end portion 140. The inner tube portion 160 connectsthe object-end portion 130 and the image-end portion 140, wherein theinner tube portion 160 is closer to the central axis of the plasticbarrel 120 than the outer tube portion 150. The inner tube portion 160includes the parallel inner surfaces 161 and the inclined inner surfaces162, wherein the parallel inner surfaces 161 are parallel to the centralaxis, and each of the inclined inner surfaces 162 has the angle with thecentral axis. The reflection reduction area 170 is disposed on the oneof the inclined inner surfaces 162 closest to the image-end opening 141,wherein the reflection reduction area 170 and the plastic barrel 120 areintegrally formed by the injection molding method. The other details ofthe optical lens module 100 have been described in the is foregoingparagraphs and will not be repeated herein.

The IR-cut filter 1100 is disposed out of the plastic barrel 120. Theimage sensor 1300 is disposed on an image surface 1200 of the opticallens module 100, and the IR-cut filter 1100 is disposed between theplastic barrel 120 and the image sensor 1300.

In FIG. 8, the non-imaging light Li would be reflected from theobject-side surface 1101 of the IR-cut filter 1100 to the reflectionreduction area 170 of the plastic barrel 120, and would be reflectedfrom the reflection reduction area 170 of the plastic barrel 120 to theobject-side surface 117 of the lens element 116 as the non-imaging lightLo, wherein the non-imaging light Lo is attenuated much from thenon-imaging light Li, so that the strength of the non-imaging light Lois much less than the strength of the non-imaging light Li, and theghost image on the image surface 1200 of the imaging apparatus 1000 hasbeen decreased.

Comparing with FIG. 1 according to the conventional imaging apparatus9000, the non-imaging light Loa would be reflected from the inner wall9521 of the plastic barrel 9520 to the object-side surface 9511 of thelens element 9510, wherein the non-imaging light Loa is attenuatedlittle from the non-imaging light Lia, so that the strength of thenon-imaging light Loa is still approach to the strength of thenon-imaging light Lia, and it results in the ghost image on the imagesurface 9700 of the conventional imaging apparatus 9000.

Therefore, according to the 7th embodiment of the present disclosure, itis favorable for reducing the ghost image resulted from the non-imaginglight totally reflected from the lens element to the image surface 1200and improving the image quality by the reflection reduction area 170disposed close to the image-end opening 141, so that the imagingapparatus 1000 can be applied to is the high-end portable electronicdevices with camera functionalities.

8th Embodiment

FIG. 9 shows an imaging apparatus 6000 according to the 8th embodimentof the present disclosure. In the 8th embodiment, an imaging apparatus6000 includes the optical lens module 600 according to the 6thembodiment of the present disclosure, an IR-cut filter 6100 and an imagesensor 6300.

In FIG. 7A, the optical lens module 600 includes the lens assembly 610,the plastic barrel 620 and the annular retaining member 680, The lensassembly 610 includes the lens elements (611-616) and is disposed in theplastic barrel 620. The plastic barrel 620 includes the object-endportion 630, the image-end portion 640, the outer tube portion 650, theinner tube portion 660 and at least three reflection reduction areas670. The object-end portion 630 includes the object-end surface 631 andthe object-end hole 632. The image-end portion 640 includes theimage-end opening 641. The outer tube portion 650 connects theobject-end portion 630 and the image-end portion 640. The inner tubeportion 660 connects the object-end portion 630 and the image-endportion 640, wherein the inner tube portion 660 is closer to the centralaxis of the plastic barrel 620 than the outer tube portion 650. Theinner tube portion 660 includes the parallel inner surfaces 661 and theinclined inner surfaces 662, wherein the parallel inner surfaces 661 areparallel to the central axis, and each of the inclined inner surfaces662 has the angle with the central axis. The reflection reduction areas670 are disposed on the inclined inner surfaces 662, especially the oneof the inclined inner surfaces 662 closest to the image-end opening 641,the object-end portion 630 and the image-end portion 640, wherein thereflection reduction areas 670 and the plastic barrel 620 are integrallyformed by an injection molding method. Therefore, it is favorable forobtaining the low reflection of the reflection reduction areas 670 andthe superior yield rate of the injection molding method, so that theimaging apparatus 6000 can be applied to the high-end portableelectronic devices with camera functionalities. The other details of theoptical lens module 600 have been described in the foregoing paragraphsand will not be repeated herein.

The IR-cut filter 6100 is disposed out of the plastic barrel 620. Theimage sensor 6300 is disposed on an image surface 6200 of the opticallens module 600, and the IR-cut filter 6100 is disposed between theplastic barrel 620 and the image sensor 6300.

9th Embodiment

FIG. 10 shows an electronic device 10 according to the 9th embodiment ofthe present disclosure. The electronic device 10 of the 9th embodimentis a smart phone, wherein the electronic device 10 includes an imagingapparatus 11, and the imaging apparatus 11 includes an optical lensmodule (not shown) according to the present disclosure. Therefore, it isfavorable for reducing the ghost image resulted from the non-imaginglight totally reflected from the lens element to the image surface andimproving the image quality. Preferably, the electronic device 10 canfurther include but not limited to a display, a control unit, a storageunit, a random access memory unit (RAM), a read-only memory unit (ROM)or a combination thereof.

10th Embodiment

FIG. 11 shows an electronic device 20 according to the 10th embodimentof the present disclosure. The electronic device 20 of the 10thembodiment is a tablet personal computer, wherein the electronic device20 includes an imaging apparatus 21, and the imaging apparatus 21includes an optical lens module (not shown) according to the presentdisclosure.

11th Embodiment

FIG. 12 shows an electronic device 30 according to the 11th embodimentof the present disclosure. The electronic device 30 of the 11thembodiment is a head-mounted display, wherein the electronic device 30includes an imaging apparatus 31, and the imaging apparatus 31 includesan optical lens module (not shown) according to the present disclosure.

Although the present disclosure has been described in considerabledetail with reference to the embodiments thereof, other embodiments arepossible. Therefore, the spirit and scope of the appended claims shouldnot be limited to the description of the embodiments contained herein.It will be apparent to those skilled in the art that variousmodifications and variations can be made to the structure of the presentdisclosure without departing from the scope or spirit of the presentdisclosure. In view of the foregoing, it is intended that the presentdisclosure cover modifications and variations of this disclosureprovided they fall within the scope of the following claims.

What is claimed is:
 1. An optical lens module, comprising: a lensassembly comprising a plurality of lens elements; and a plastic barrel,wherein the lens assembly is disposed in the plastic barrel, and theplastic barrel comprises: an object-end portion comprising an object-endsurface and an object-end hole; an image-end portion comprising animage-end opening; an outer tube portion connecting the object-endportion and the image-end portion; an inner tube portion connecting theobject-end portion and the image-end portion, wherein the inner tubeportion is closer to a central axis of the plastic barrel than the outertube portion is to the central axis and comprises: a plurality ofparallel inner surfaces parallel to the central axis; and a plurality ofinclined inner surfaces, wherein each of the inclined inner surfaces hasan angle with the central axis; and at least one reflection reductionarea disposed on at least one of one of the inclined inner surfacesclosest to the image-end opening and one of the parallel inner surfacesclosest to the image-end opening, wherein the reflection reduction areaand the plastic barrel are integrally formed by an injection moldingmethod.
 2. The optical lens module of claim 1, wherein an angle betweenthe one of the inclined inner surfaces closest to the image-end openingand the central axis is α, and the following condition is satisfied:1.0 degrees<α<25.0 degrees.
 3. The optical lens module of claim 2,wherein the angle between the one of the inclined inner surfaces closestto the image-end opening and the central axis is α, and the followingcondition is satisfied:2.0 degrees<α<20.0 degrees.
 4. The optical lens module of claim 1,wherein at least three of the lens elements are connected to theparallel inner surfaces.
 5. The optical lens module of claim 1, whereina number of the parallel inner surfaces is at least six.
 6. The opticallens module of claim 1, wherein a number of the reflection reductionarea is at least three, and the three reflection reduction areas aredisposed on the one of the inclined inner surfaces closest to theimage-end opening, the object-end portion and the image-end portion,respectively.
 7. The optical lens module of claim 1, wherein thereflection reduction areas are formed by sand-blasting indirectly. 8.The optical lens module of claim 1, further comprising: an annularretaining member for disposing the lens assembly in the plastic barrel.9. The optical lens module of claim 8, wherein at least one of theparallel inner surfaces is connected to the annular retaining member.10. The optical lens module of claim 1, wherein a surface roughness ofthe reflection reduction area is Ra, and the following condition issatisfied:0.18μm<Ra<μm.
 11. The optical lens module of claim 1, wherein theplastic barrel is made of polycarbonate material.
 12. The optical lensmodule of claim 11, wherein a refractive index of one is of the lenselements closest to the image-end opening is n, and the followingcondition is satisfied:1.45<n<1.62.
 13. The optical lens module of claim 1, wherein an outerdiameter of one of the lens elements closest to the image-end opening isφ, and the following condition is satisfied:5.85 mm<φ<9.5 mm.
 14. An imaging apparatus, comprising: the optical lensmodule of claim 1; an IR-cut filter (infrared-cut filter) disposed outof the plastic barrel; and an image sensor, wherein the image sensor isdisposed on an image surface of the optical lens module, and the IR-cutfilter is disposed between the plastic barrel and the image sensor. 15.An electronic device, comprising: the imaging apparatus of claim 14.